WO2014170582A1 - Method for restoring service in an ims network - Google Patents

Abstract

The present invention concerns a method for restoring service in an IMS network, comprising the following steps: a service request (N° 1) targeting a user of said IMS network (1) is received (E'1) by an I-CSCF server (N° 1) of said IMS network (1); said I-CSCF server (N° 1) sends (E'2), to the HSS server of the IMS network (1) responsible for said user, a request aimed at learning the identity of the nominal S-CSCF server (N° 1) associated with said user; the HSS server selects (E'6) a new S-CSCF server (N° 2) capable of providing all the services authorised for the user, records the assigning of said new S-CSCF server (N° 2) to the user, and provides the I-CSCF server (N° 1) with an identifier of the new S-CSCF server (N° 2) assigned to the user; the I-CSCF server (N° 1) takes into account (E'7) said identifier of the new S-CSCF server (N° 2), and forwards the service request (N° 1) to said new S-CSCF server (N° 2).

Description

 SERVICE RESTORATION METHOD IN IMS NETWORK

The present invention relates to communication networks of IP ("Internet Protocol") type, and in particular those of IP networks that are able to implement advanced session control protocols. IP networks include the transmission of conversational data, in the context of services such as "VoIP" (VoIP), "Content Sharing", or "Instant Messaging".

 More particularly, the present invention relates to the routing of a service request, for example a VoIP call, to a client device belonging to an IMS network (initials of the words "IP Multimedia Subsystem" meaning "Multimedia subsystem on IP ").

 It will be noted in this regard that, in the context of the present invention, a client device ("User Equipment" in English) is said to "belong" to the network of a given operator when the user of this client device has a account with this operator, regardless of the access network used by the client device to connect to the network of the operator. These client devices may for example be a fixed or mobile terminal, or a residential gateway (English) or located in a company, or a network operator gateway ("Voice Gateway" in English) such as a DSLAM-SIP (DSLAM) are the initials of the words "Digital Subscriber Line Access Multiplexer" meaning "Digital Subscriber Line Access Multiplexer", it is a device that collects DSL data traffic that passes through on a number of telephone lines).

Conventional advanced session control protocols, such as the SIP protocol (initials of the words "Session Initiation Protocol" meaning "Session Initiation Protocol"), use so-called messages. "signaling", which are messages enabling a terminal to request a connection with another terminal, or also messages indicating that a telephone line is busy, or signaling that the called telephone rings, or signaling that such a telephone is connected to the network and can be attached in one way or another.

 The SIP protocol has been defined by the Internet Engineering Task Force (IETF) in RFC 3261. This protocol allows the establishment, modification and termination of multimedia sessions in a network using the IP protocol. The SIP protocol was then extended in particular in RFC 3265. This extension allows event notification procedures.

The SIP protocol is used in particular in the IMS-type infrastructures, mentioned above. The IMS has been defined by the 3GPP standardization body ("3 ^rd Generation Partnership Project") and TISPAN ("Telecommunications and Internet Converged Services and Protocols for Advanced Networking"). It is a network architecture introduced by 3GPP for mobile networks, then taken over by TISPAN for fixed networks. This architecture enables the dynamic establishment and control of multimedia sessions between two clients as well as the reservation of resources at the level of the network for transporting multimedia streams. Through this architecture, network operators can conveniently implement a management policy, provide a predetermined Quality of Service, and calculate the amounts to be billed to customers. IMS currently provides access to services such as telephony, video telephony, and instant messaging, which it also manages. For example, Instant Messaging (IM), also known as "chat" (a name derived from the English word "chat" meaning "chatter"), allows the instantaneous exchange of messages. textual and file, this which allows an interactive dialogue between two users connected to the same network (such as the Internet).

 When a user wishes to benefit from the services offered by an IMS network, he sends signaling messages to the network that may include various types of requests.

 First, the client device of the user must, with exceptions (such as certain emergency calls), register on the network. When the network is unable to link this record to a previous record (for example due to a network failure, or following a client-device shutdown for a duration longer than a predetermined value), the record is considered being an initial recording. After an initial registration, the user's client device must periodically send the network a request to confirm that it wishes to maintain its registration.

 In order to be able to register the client devices, the networks

IMSs include one or more registration servers, referred to as "S-CSCFs" (initials of the English words "Serving-Call Server Control Function" meaning "Server Call Session Control Function"), suitable (among other functions) manage the registration procedure of devices connected to the network.

In addition, these networks include one or more servers, called "l-CSCF" servers (initials of the English words "Interrogating- Call Server Control Function" meaning "Interrogating Call Session Control Function") - moreover often combined physically with the servers of type S-CSCF to constitute servers denoted "l / S-CSCF" - which, at the time of the registration of a device-client, interrogate a server called "HSS" (initials of the English words " Home Subscriber Server "means" Subscriber Subscriber Server ") so that you can select an S-CSCF server with the capabilities required to provide all services authorized for the user-device user. These "capabilities" are precisely defined in Chapter 6.7 of the 3GPP Specification TS 29.228 (see in particular Table 6.7).

 HSS servers are the equivalent in IP networks of "HLR" servers (initials of the words "Home Location Register" meaning "Link Location Registry") used in GSM networks. Each HSS server can access a client database defined in 3GPP TS 23.008 specification (see in particular Section 3): this client data concerns, for example, for each user of the IMS network, the state of registration of the associated client device, as well as authentication and location data. In the context of the present invention, such a database (whether or not it obeys specification TS 23.008) will be referred to as "user profile".

 After an S-CSCF server has been assigned to it, each user can use a number of services during the current connection. For example, these services may be offered automatically to all users of the IMS network. It can also be services to which this user has subscribed to the network operator, and which are automatically made available. Finally, they may be services that the user can use after issuing an appropriate request (SIP SUBSCRIBE).

These services include audiovisual applications as mentioned above. It can also be a subscription to the state of a resource, in which case event notifications (SIP NOTIFY) are sent to the client device as soon as the state of the resource changes; for example, when the user of a client device has a mailbox on the network, he can be informed each time a message has been recorded on this mailbox; a user can, likewise, ask to be notified of the registration status of his own client device.

 3GPP defined in the TS 23.380 specification a procedure to restore the IMS service in the event of an S-CSCF server failure. In particular, this specification proposes in Section 4.3.3 the selection by an l-CSCF server of a new S-CSCF server for the processing of incoming calls, so that a user whose nominal S-CSCF server is has failed to be aware of the failure and calls for it continue to be issued (the notion of "nominal" S-CSCF server is defined in Section 3.2.2 of TS 23.008 mentioned above). -above).

 However, the authors of the present invention have realized that, if this restoration procedure is adequate in the case of an IMS network comprising a single l-CSCF server and able to always select the same replacement S-CSCF server, it is inadequate. in the case of a usual IMS network, which comprises either several l-CSCF servers (the most frequent case, for reasons of network capacity), or a single l-CSCF server (of the "stateless proxy" type) which can a priori select alternative S-CSCF servers different from one service request to another.

 For example, when the network includes multiple I-CSCF servers, these l-CSCF servers are in mutual competition over the restore procedures. This problem is illustrated below by an example, with reference to FIG.

 During a step E1, a service request (No. 1) targeting a certain user of an IMS network is received by an I-CSCF server (No. 1) of this network.

During a step E2, this l-CSCF server No. 1 initiates a so-called "first location procedure"("LIRDiameter" message) to the HSS server in charge of said user, to know the identity of the nominal S-CSCF server (N ° 1) assigned to this user.

 During a step E3, the HSS server responds to the l-CSCF server No. 1 ("LIA Diameter" message) by providing an identifier of the nominal S-CSCF server; it is for example an S-CSCF server called "S3".

 This "first" location procedure, implemented in steps E2 and E3, is described in TS 29.228 (mentioned above) in Chapter 6.1 .4 (see in particular Table 6.1.4.1). In the "Diameter" exchanges between an l-CSCF server and an HSS server, the user is identified by means of his IMPU (initials of the words "IP Multimedia PUblic identity" meaning "Public Identity for Multimedia IP").

During a step E4, the l-CSCF server No. 1 attempts to join the S-CSCF server S3 to transmit the request No. 1, but the attempt fails; this may be due to a failure of the S-CSCF server S3, or failure of the connection between the server-CSCF No. 1 and ^r is the S-CSCF S3 dreamer.

 During a step E5, the l-CSCF server No. 1 therefore initiates a restoration procedure in accordance with the aforementioned TS 23.380 specification. To do this, the l-CSCF server No. 1 initiates a "second location procedure", in which the l-CSCF server No. 1 sends a "capacity request" (second message "Diameter LIR") to the server HSS, to find out what capabilities an S-CSCF server must have in order to provide all the services authorized for that user.

 During a step E6, the server HSS responds to the server l-CSCF No.

1 (second message "Diameter LIA") indicating which are said capabilities.

During a step E7, the l-CSCF server No. 1 selects a new S-CSCF server (S-CSCF No. 2) having the capabilities required to provide all the services authorized for this user; for example, assume that the selected S-CSCF server has the identifier "S2". The l-CSCF server No. 1 then sends the request No. 1 to this server S-CSCF No. 2 (ie, S2).

 During a step E8, a new service request (No. 2), targeting the same user as the service request No. 1, is received by an I-CSCF server (No. 2) of the IMS network; it will be noted that this l-CSCF server No. 2 may possibly be identical to the l-CSCF server No. 1.

At a step E9, similar to the step E2 above, the I- CSCF server # 2 initiates a "first" procedure loca ^l ization (message "Diameter ITA") to the HSS in charge of said user for the identity of the nominal S-CSCF (No. 1) server associated with this user.

 In a step E10, analogous to step E3 above, the HSS server responds to the l-CSCF server No. 2 ("LIA Diameter" message) by providing an identifier of the nominal S-CSCF server, i.e. S3.

 During a step E1 1, analogous to step E4 above, the l-CSCF server No. 2 attempts to join the S-CSCF server S3 to send him the request No. 2, and the attempt fails.

 At the same time, during a step E12, the S-CSCF server No. 2 updates the HSS server with its own reference (ie, S2) ("SAR Diameter" message), since, following the step E7 above, above, this S-CSCF server S2 considers that it is henceforth the nominal S-CSCF server for said user. The HSS server confirms this update ("Diameter SAA" message).

 During a step E13, similar to step E5 above, the server I-

CSCF # 2 sends a capability request (second "Diameter LIR" message) to the HSS server, to find out what capabilities an S-CSCF server must have in order to provide all the authorized services for that user. In a step E14, analogous to step E6 above, the server HSS responds to the server l-CSCF No. 2 (second message "Diameter LIA") indicating which are said capabilities.

 During a step E15, analogous to step E7 above, the I-CSCF server No. 2 selects a new S-CSCF server (No. 3) having the capabilities required to be able to provide all the authorized services. for this user; it is for example an S-CSCF server called "S4". Indeed, according to the state of the art, the server S-CSCF No. 3 selected by the server l-CSCF No. 2 may, where appropriate, be identical to the server S-CSCF No. 2, but may also to be distinct from it. The l-CSCF server No. 2 then sends the request No. 2 to this server S-CSCF No. 3 (i.e., S4).

 During a step E16, analogous to step E12 above, the S-CSCF server No. 3 then updates the HSS server with its own reference (ie, S4) ("SAR Diameter" message), since following the previous step E15, this S-CSCF server S4 considers that it is henceforth the nominal S-CSCF server for said user. The HSS server confirms this update ("Diameter SAA" message).

 But, during a step E17, calls initiated on the server S-CSCF No. 2 (ie, S2) are broken when the server HSS informs the latter that a new server S-CSCF (ie, S4) is now nominally in charge of the user. Indeed, in an IMS network, there can be from the point of view of the HSS server only one nominal S-CSCF server assigned to a given user. This user may see some of his incoming calls released, which can be very unfortunate, especially if the traffic to him is important (for example if said user is a company and its client device is a PABX).

The same problem is found in a method disclosed by the application EP 1988662. This method starts with steps similar to the steps E1 and E2 above, but then it is the HSS server itself. which detects that the nominal S-CCF server is down. The HSS server then chooses a new S-CSCF server (let's call it "S5"), and provides an identifier for this new S-CSCF server S5 to the l-CSCF server, which then makes the request to this S-CSCF server. S5. In parallel, according to this method, the HSS server notifies the user via the S-CSCF server S5 that he must re-register on the network. However, when the user re-register, he is naturally assigned a new nominal S-CSCF server (let's call it "S6"), but nothing in the process according to EP 1988662 comes to guarantee that this S-CSCF nominal server S6 will be the same as the S-CSCF S5 server! The user may see some of his incoming calls released, as in the example above.

 The present invention thus relates to a service restoration method in an IMS network, comprising the following steps:

 a) a service request for a user of said IMS network is received by an I-CSCF server of this IMS network,

 b) said l-CSCF server sends to the HSS server of the IMS network in charge of said user a request to know the identity of the nominal S-CSCF server associated with said user,

 c) the HSS server selects a new S-CSCF server capable of providing all the authorized services for the user, and provides the l-CSCF server with an identifier of the new S-CSCF server, and d) the l-CSCF server. takes into account said identifier of the new S-CSCF server, and forward the service request to this new S-CSCF server.

 The method is notable in that the HSS server records the assignment to the user of the new S-CSCF server.

Thanks to the invention, it can be indicated to any l-CSCF server that has received a service request targeting a certain user, not only (in a conventional manner) the identity of the nominal S-CSCF server for that user. user, but also, following a failure of this nominal S-CSCF server, the identity of a single S-CSCF server to process the service requests for this user, instead of the S-CSCF server failed. This avoids contradictory reselections according to the state of the art, and the loss of calls that result.

 Said HSS server may be informed in various ways that said user's nominal S-CSCF server is down or unreachable. According to particular features, said method further comprises, between said steps b) and c), the following steps:

 said HSS server responds to said l-CSCF server by providing an identifier of said nominal S-CSCF server,

 the l-CSCF server attempts to join this nominal S-CSCF server, but the attempt fails, and

 the l-CSCF server sends the HSS server a request for capabilities to know what capabilities an S-CSCF server must have in order to provide all the authorized services for said user.

 According to other particular characteristics, in order to record the assignment to the user of said new S-CSCF server, the HSS server registers an identifier of this new S-CSCF server in a dedicated piece of information of the user's profile.

With these arrangements, if another service request for the same user is subsequently received by a second server L-CSCF (different or different from the aforementioned first server L-CSCF), and said second server l-CSCF queries the server HSS to know the identity of the nominal S-CSCF server associated with this user, the HSS server may advantageously read said information element, and respond to the second l-CSCF server by providing an identifier of said (single) assigned S-CSCF server to the user. Correlatively, the invention relates to an HSS server of an IMS network, comprising means for:

 receiving, from an L-CSCF server, a request to know the identity of the nominal S-CSCF server associated with a user, of which said HSS server is responsible, of said IMS network,

 responding to said l-CSCF server by providing an identifier of said nominal S-CSCF server,

 receiving, from the l-CSCF server, a capability request to know what capabilities an S-CSCF server must have in order to provide all the authorized services for said user,

select a new S-CSCF server capable of providing all the services authorized for the user, and

 providing the l-CSCF server with an identifier of said new S-CSCF server.

Said HSS server is remarkable in that it also has means for recording the assignment to the user of the new S-CSCF server.

 The advantages offered by this HSS server are essentially the same as those offered by the correlative method succinctly set forth above.

 According to particular features, said HSS server can access an equivalence table whose each element is a pair of S-CSCF servers of said IMS network such that the second (respectively, first) S-CSCF server of this pair has at least all the capabilities of the first (respectively, second) S-CSCF server of this couple.

 With these provisions, the HSS server can conveniently:

select a new S-CSCF server capable of providing all the services authorized for the user, and providing the l-CSCF server with an identifier of a new S-CSCF server assigned to the user, in the form of an index pointing to an element of said equivalence table.

 Note that it is possible to realize the devices succinctly described above in the context of software instructions and / or in the context of electronic circuits.

 The invention also relates to a computer program downloadable from a communication network and / or stored on a computer readable medium and / or executable by a microprocessor. This computer program is notable in that it includes instructions for performing the steps of any of the service restoration methods succinctly set forth above, when run on a computer.

 The advantages offered by this computer program are essentially the same as those offered by said method.

 Other aspects and advantages of the invention will appear on reading the detailed description below of particular embodiments, given by way of non-limiting examples. The description refers to the accompanying drawings, in which:

 FIG. 1, described above, schematically illustrates the successive steps of a conventional method of service restoration in the event of failure of an S-CSCF server,

 FIG. 2 schematically represents, by way of example, a system for providing multimedia services capable of implementing the invention, and

 - Figure 3 schematically illustrates the successive steps of a service restoration method in case of failure of an S-CSCF server, according to one embodiment of the invention.

The system illustrated in FIG. 2 implements an IMS 1 type network architecture, as briefly presented above. The Multimedia services offered by this IMS network 1 may include telephony services, video telephony, content-sharing ("content-sharing"), Presence, Instant Messaging, or television. These services are available to the user of a device-client ("User Equipment" or UE in English) 10 belonging to the network 1, which allows the UE 10 to exchange multimedia streams and signaling signals. session control according to the SIP protocol, for example with a UE 1 1.

 This UE 10 may be a fixed or mobile terminal, or a home or enterprise gateway, having SIP signaling means and may include means for rendering audiovisual content.

 As shown in FIG. 2, this IMS network 1 comprises, in addition to an IP transport infrastructure (not shown):

 • at least one S-CSCF server; the S-CSCF server 27 manages in particular the procedure for registering the devices connected to the network 1; the S-CSCF server 27 also manages the routing of the signaling between the UE 10 and the voicemail servers VM 25, Instant Messaging IM 26, and telephony TAS 29;

• at least one l-CSCF server; the l-CSCF server 22 notably manages the routing towards other client devices managed by the same IMS network 1 and the routing of the signaling between this IMS network 1 and other networks;

At least one P-CSCF server (initials of the English words "Proxy-Call Server Control Function" meaning "Proxy Call Session Control Function"); the P-CSCF server 21 serves as a connection entity between the network 1 and the access network used by the UE 10; the P-CSCF server 28 serves as a connection entity between the network 1 on the one hand, and the UE 1 1 or an access network used by the UE 11 on the other hand; all SIP signaling exchanged between the EU 10 (respectively 1 1) and the S-CSCF server 27 passes through the P-CSCF server 21 (respectively 28);

 At least one database server, of the HSS type; the HSS server 24 contains the profile of the user of the UE 10 in terms of authentication data, location and subscribed services;

At least one VM-25 voice mail server ("message-summary"); the server VM 25 manages an eventual subscription of the UE 10 to the message depot / consultation events for the user of the UE 10, and notifies the client device 10 at the occurrence of these events. ;

 • at least one IM 26 instant messaging server (mentioned above); in case of subscription of the user of the UE 10 to the instant messenger service, this user can chat "instantly" online with other users of this service; and

 At least one TAS 29 telephony server; the TAS server manages any telephone services to which the user of the UE 10 has subscribed with the network operator 1, such as the presentation of the number or call forwarding.

 VM 25 Voicemail Messaging Servers

Instant IM 26, and TAS telephony 29 are examples of so-called AS (initials of the English words "Application Servers" meaning "Application Servers").

 According to 3GPP Standard TS 24.229 (see in particular version 1.1.5.0 of this standard, clause 5.4.3.3, items 3C and 3D, and Annex I), when S-CSCF 27 receives server l-CSCF 22 a service request for the user who has previously registered the UE 10:

e) the S-CSCF 27 verifies that this service complies with the subscription of this user to the operator of the network 1, and f) in the event of compliance, S-CSCF 27 forward the request to an appropriate EU 10 contact address; for example, if the UE 10 is a VoIP telephone, and if the required service is a telephone call to the telephone number of the user of the UE 10, said contact address is usually an IP address associated with said number phone.

 In particular, in order to remedy the problems set out above with reference to FIG. 1, the invention proposes a new service restoration method for managing incoming requests. FIG. 3 illustrates an embodiment of this method according to the invention.

 The steps ΕΊ to E'5 are similar to the steps E1 to E5 described above with reference to FIG.

 During a step E'6, unlike the state of the art, it is the HSS server that selects the new S-CSCF server to assign the user to replace the failed S-CSCF server.

 To do this, the HSS server operates an equivalence table according to the invention to which it has access.

This table contains equivalences in terms of "capabilities" C _b where i = 1.2, as mentioned above, of all S-CSCF servers or some of them (in fact, the TS 29.228 specification distinguishes between mandatory and optional capabilities, but the present invention is limited to mandatory capabilities).

The equivalence table can be constructed as follows. The first column of this table represents a list of S-CSCF servers. A second column indicates, on the same line as a given S-CSCF server of the first column, an "equivalent" S-CSCF server, that is to say an S-CSCF server having at least the capacities of said server S-CSCF given, and who can replace this server S-CSCF given in case of failure. According to a first variant, the equivalence table further comprises a third column containing an index referencing each pair S-CSCF / S-CSCF-equivalent. In this first variant, the contents of the equivalence table are known, not only of the HSS server, but also of all the I-CSCF servers of the IMS network.

 According to a second variant, the equivalence table does not include this third column. In this second variant, the contents of the equivalence table are known to the HSS server, but are not shared with the l-CSCF servers.

 For example, consider a set of four S-CSCF servers with the following capabilities:

51 [C _lt C _2, C _3]

52 [C _lt C _{2 l} C ₃

 53 [C, and

54 [C, C ₂ ].

 If, for example, the first variant mentioned above is chosen, then the equivalence table is as follows:

A similar example is seen that S4 has S1 (index 6), but that meanwhile S1 has no equivalent since S4 S4 lacks the capacity C ₃ to regain the overall capacity of S1. In the exemplary embodiment considered, it is the S-CSCF server S3 that had been nominally associated with the user. The HSS server can therefore select the S-CSCF server S1 (index 3), or the S-CSCF server S2 (index 4), or the S-CSCF server S4 (index 5) instead of the S-CSCF server S3.

 Suppose the HSS server selects the S-CSCF server S1. The HSS server then updates the user's profile accordingly, for example by entering an identifier of the S-CSCF server S1 in an "S-CSCF-Restoration-Info" field, as defined in the TS 29.229 specification. 3GPP; more precisely, this "S-CSCF-Restoration-Info" field will, for the implementation of the present invention, include a dedicated piece of information, in which the HSS server will write said identifier.

 Note in passing that if, subsequently, the HSS server receives a request for capabilities concerning another user who was also associated with the S-CSCF server S3 as a nominal S-CSCF server, the HSS server can advantageously select (for example) the S-CSCF server S2 for this other user, in order to perform load sharing to all the S-CSCF servers equivalent to S3.

The HSS then responds to the server l-CSCF No. 1 (second message "Diameter LIA") by providing an identifier of the new server S-CSCF (ie, S1) assigned to the user. More specifically, in the context of the first variant mentioned above, the HSS server searches for the S-CSCF server S3 in the equivalence table, finds therein the information of equivalence with S1, reads the corresponding index (at know, "3") and sends this index "3" to the server l-CSCF No. 1 to indict the selection of the server S-CSCF S1. In the context of the second variant mentioned above, the server HSS sends to the server l-CSCF No. 1, in a form other than said index, an identifier of said server S-CSCF (ie, S1) that the HSS server selected; the advantage of this second variant lies in the fact that it is not necessary to share the equivalence table with the l-CSCF servers, resulting in savings in terms of storage and operating costs compared to in the first variant.

 During a step E7, contrary to the state of the art, the server I-

CSCF # 1 receives this identifier from the HSS server and takes it into account. The server l-CSCF No. 1 therefore follows the service request No. 1 to the server S1 as server S-CSCFN ° 2.

 During a step E'8, similar to the step E8 described above with reference to FIG. 1, a new service request (No. 2) for the same user as the service request (No. 1) is received by a second I-CSCF server (No. 2) of the IMS network (this second I-CSCF server (No. 2) may or may not be different from the first server l-CSCF (No. 1)).

 During a step E'9, similar to the step E9 described above with reference to FIG. 1, the l-CSCF server No. 2 contains a "first" location procedure ("LIR Diameter" message) to the HSS server.

 In a step ΕΊ 0, similar to the step E10 described above with reference to FIG. 1, the server HSS responds to the server l-CSCF No. 2 by supplying it with an identifier of the new server S-CSCF assigned to the user (ie, S1).

 During a step ΕΊ 1, the l-CSCF server No. 2 receives this identifier from the HSS server and takes it into account. It therefore follows the request No. 2 to the S-CSCF server S1, that is to say to the same server S-CSCF that the one to which the server l-CSCF No. 1 has forwarded the request No. 1.

In parallel, during a step ΕΊ 2, similar to step E12 described above with reference to FIG. 1, the S-CSCF server No. 2 then updates the HSS server with its own reference (ie, S1 ) (message "Diameter SAR"), so that the S-CSCF server No. 2 is now the nominal S-CSCF server in charge of said user. The HSS server confirms this update ("Diameter SAA" message).

 It can thus be seen that, thanks to the invention, the risks of selecting multiple restoration S-CSCF servers are avoided; early releases or loss of calls are therefore also avoided.

 The implementation of the invention within nodes of an IMS network, in particular within HSS servers, can be achieved by means of software and / or hardware components.

 The software components can be integrated into a typical network node management computer program. Therefore, as indicated above, the present invention also relates to a computer system. This computer system conventionally comprises a central processing unit controlling signals by a memory, as well as an input unit and an output unit. In addition, this computer system can be used to execute a computer program comprising instructions for implementing the service restoration method according to the invention.

 Indeed, the invention also relates to a downloadable computer program from a communication network comprising instructions for performing the steps of a service restoration method according to the invention, when it is executed on a computer. This computer program may be stored on a computer readable medium and may be executable by a microprocessor.

This program can use any programming language, and be in the form of source code, object code, or intermediate code between source code and object code, such as in a partially compiled form, or in any another desirable form. The invention also relates to an information carrier, irremovable, or partially or completely removable, readable by a computer, and comprising instructions of a computer program as mentioned above.

 The information carrier may be any entity or device capable of storing the program. For example, the medium may comprise storage means, such as a ROM, for example a CD ROM or a microelectronic circuit ROM, or a magnetic recording medium, such as a hard disk, or a USB key. ("USB flash drive" in English).

 On the other hand, the information medium may be a transmissible medium such as an electrical or optical signal, which may be conveyed via an electrical or optical cable, by radio or by other means. The computer program according to the invention can in particular be downloaded to an Internet type network.

 As a variant, the information carrier may be an integrated circuit in which the program is incorporated, the circuit being adapted to execute or to be used in the execution of the service restoration method according to the invention.

Claims

A service restore method in an IMS network, comprising the steps of:

 a) a service request (No. 1) for a user of said IMS network (1) is received (ΕΊ) by an I-CSCF server (No. 1) of this IMS network (1),

 b) said l-CSCF server (No. 1) sends (E'2) to the HSS server of the IMS network (1) in charge of said user a request to know the identity of the nominal server S-CSCF (No. 1) associated with the user,

 c) the HSS server selects (E'6) a new S-CSCF server (No. 2) able to provide all the services for the user, and provides the server l-CSCF (No. 1) an identifier said new S-CSCF server (No. 2), and

 d) the server l-CSCF (No. 1) takes into account (E7) this identifier of the new server S-CSCF (No. 2), and forward the service request (No. 1) to this new server S- CSCF (No.%), characterized in that the HSS server records the assignment to the user of the new S-CSCF server (No. 2).

2. Service restoration method according to claim 1, characterized in that it further comprises, between said steps b) and c), the following steps:

 said HSS server responds (E'3) to said l-CSCF server (No. 1) by supplying an identifier of said nominal S-CSCF server (No. 1),

- the l-CSCF server (No. 1) tries (E'4) to join nominal S-CSCF server (No. 1), but the attempt fails, and

- the server l-CSCF (N ° 1) sends (E'5) to the server HSS a request of capacities aiming to know what capacities a server S-CSCF must have to be able to provide all the authorized services for said user.

3. Service restoration method according to claim 1 or claim 2, characterized in that, to record the assignment to the user of said new S-CSCF server (No. 2), the HSS server registers an identifier of that server. new S-CSCF server (No. 2) in a dedicated information element of the user's profile.

4. HSS server of an IMS network, comprising means for:

receiving, from an L-CSCF server (No. 1), a request to know the identity of the norrinal S-CSCF server (N ° 1) associated with a user, whose said HSS server is responsible for of said IMS network (1),

 responding to said l-CSCF server (No. 1) provided an identifier of said nominal S-CSCF server (No. 1),

 receiving, from the l-CSCF server (No. 1), a capacity request to know what capabilities an S-CSCF server must have in order to provide all the authorized services for said user,

 select a new S-CSCF server (N ° 2) capable of providing all the authorized services for the user, and

 providing the l-CSCF server (No. 1) with an identifier of said new S-CSCF server (No. 2),

characterized in that it further has means for storing the assignment to the user of the new S-CSCF server (No. 2).

5. HSS server according to claim 4, characterized in that it can access an equivalence table where each element is a pair of S-CSCF servers of said IMS network (1) such as the second (respectively, first) server S-CSCF of this couple owns at least all the capabilities of the first (respectively, second) S-CSCF server of this couple.

A non-removable, or partially removable, or removable data storage means having computer program code instructions for performing the steps of a service restoration method according to any one of claims 1 to 3.

7. Computer program downloadable from a communication network and / or stored on a computer readable medium and / or executable by a microprocessor, characterized in that it comprises instructions for executing the steps of a method of service restoration according to any one of claims 1 to 3 when executed on a computer.